Real time evaluation and correction of nonlinear errors in single frequency interferometers

C. H. Wang; A. T. Augousti; J. Mason

doi:10.1177/014233120002200505

Real time evaluation and correction of nonlinear errors in single frequency interferometers

C. H. Wang, A. T. Augousti, J. Mason

Research output: Contribution to journal › Article › peer-review

Abstract

Nonlinear errors in single frequency interferometers are mainly caused by inaccuracies in quadrature signals. A novel design for real time correction of these errors has been developed using a technique based on the use of a microcontroller and computational analogue circuits. The former is responsible for the detection of these nonlinear errors while the latter is responsible for their correction. As a result, errors arising from nonlinearity are reduced to about 0.3% of an interference fringe over a bandwidth for the quadrature signals ranging from d.c. to 100 kHz. Moreover, a simplified method for evaluating the degree of these nonlinear errors without resorting to a length standard is also presented. Finally, a demonstration application of this new correction technique to a laser interferometer was carried out and experimental results are given.

Original language	English
Pages (from-to)	405-412
Journal	Transactions of the Institute of Measurement and Control
Volume	22
Issue number	5
DOIs	https://doi.org/10.1177/014233120002200505
Publication status	Published - Dec 2000

Keywords

error correction
laser interferometer
nonlinear errors
Physics

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10.1177/014233120002200505

http://dx.doi.org/10.1177/014233120002200505

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title = "Real time evaluation and correction of nonlinear errors in single frequency interferometers",

abstract = "Nonlinear errors in single frequency interferometers are mainly caused by inaccuracies in quadrature signals. A novel design for real time correction of these errors has been developed using a technique based on the use of a microcontroller and computational analogue circuits. The former is responsible for the detection of these nonlinear errors while the latter is responsible for their correction. As a result, errors arising from nonlinearity are reduced to about 0.3\% of an interference fringe over a bandwidth for the quadrature signals ranging from d.c. to 100 kHz. Moreover, a simplified method for evaluating the degree of these nonlinear errors without resorting to a length standard is also presented. Finally, a demonstration application of this new correction technique to a laser interferometer was carried out and experimental results are given.",

keywords = "error correction, laser interferometer, nonlinear errors, Physics",

author = "Wang, \{C. H.\} and Augousti, \{A. T.\} and J. Mason",

year = "2000",

month = dec,

doi = "10.1177/014233120002200505",

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pages = "405--412",

journal = "Transactions of the Institute of Measurement and Control",

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T1 - Real time evaluation and correction of nonlinear errors in single frequency interferometers

AU - Wang, C. H.

AU - Augousti, A. T.

AU - Mason, J.

PY - 2000/12

Y1 - 2000/12

N2 - Nonlinear errors in single frequency interferometers are mainly caused by inaccuracies in quadrature signals. A novel design for real time correction of these errors has been developed using a technique based on the use of a microcontroller and computational analogue circuits. The former is responsible for the detection of these nonlinear errors while the latter is responsible for their correction. As a result, errors arising from nonlinearity are reduced to about 0.3% of an interference fringe over a bandwidth for the quadrature signals ranging from d.c. to 100 kHz. Moreover, a simplified method for evaluating the degree of these nonlinear errors without resorting to a length standard is also presented. Finally, a demonstration application of this new correction technique to a laser interferometer was carried out and experimental results are given.

AB - Nonlinear errors in single frequency interferometers are mainly caused by inaccuracies in quadrature signals. A novel design for real time correction of these errors has been developed using a technique based on the use of a microcontroller and computational analogue circuits. The former is responsible for the detection of these nonlinear errors while the latter is responsible for their correction. As a result, errors arising from nonlinearity are reduced to about 0.3% of an interference fringe over a bandwidth for the quadrature signals ranging from d.c. to 100 kHz. Moreover, a simplified method for evaluating the degree of these nonlinear errors without resorting to a length standard is also presented. Finally, a demonstration application of this new correction technique to a laser interferometer was carried out and experimental results are given.

KW - error correction

KW - laser interferometer

KW - nonlinear errors

KW - Physics

U2 - 10.1177/014233120002200505

DO - 10.1177/014233120002200505

M3 - Article

SN - 0142-3312

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SP - 405

EP - 412

JO - Transactions of the Institute of Measurement and Control

JF - Transactions of the Institute of Measurement and Control

IS - 5

ER -

Real time evaluation and correction of nonlinear errors in single frequency interferometers

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Keywords

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